Ubuntu Manpage: pycrc - a free, easy to use Cyclic Redundancy Check (CRC) calculator and C source code generator.

NAME

       pycrc - a free, easy to use Cyclic Redundancy Check (CRC) calculator and C source code generator.

SYNOPSIS


       python pycrc.py [OPTIONS]

DESCRIPTION

pycrc[1] is a CRC reference implementation in Python and a C source code generator for parametrised CRC
models. The generated C source code can be optimised for simplicity, speed or small memory footprint, as
required on small embedded systems. The following operations are implemented:

• calculate the checksum of a string (ASCII or hex)

• calculate the checksum of a file

• generate the header and source files for a C implementation.

pycrc supports the following variants of the CRC algorithm:

• bit-by-bit or bbb: the basic algorithm which operates individually on every bit of the augmented
message (i.e. the input data with Width zero bits added at the end). This algorithm is a
straightforward implementation of the basic polynomial division and is the easiest one to understand,
but it is also the slowest one among all possible variants.

• bit-by-bit-fast or bbf: a variation of the simple bit-by-bit algorithm. This algorithm still iterates
over every bit of the message, but does not augment it (does not add Width zero bits at the end). It
gives the same result as the bit-by-bit method by carefully choosing the initial value of the
algorithm. This method might be a good choice for embedded platforms, where code space is more
important than execution speed.

• table-driven or tbl: the standard table driven algorithm. This is the fastest variant because it
operates on one byte at a time, as opposed to one bit at the time. This method uses a look-up table
(usually of 256 elements), which might not be acceptable for small embedded systems. The number of
elements in the look-up table can be reduced with the --table-idx-width command line switch. The
value of 4 bits for the table index (16 elements in the look-up table) can be a good compromise
between execution speed and code size.

The --slice-by option enables a variant of the table-driven algorithm that operates on 32 bits of
data or more at a time rather than 8 bits. This can dramatically speed-up the calculation of the CRC,
at the cost of increased code and data size. Note: this option is experimental and not well-tested.
Check your results and please raise bugs if you find problems.

OPTIONS

--version
show the program version number and exit.

-h, --help
show this help message and exit.

--verbose
be more verbose; in particular, print the value of the parameters and the chosen model to stdout.

--check-string=STRING
calculate the checksum of a string (default: “123456789”). If the string contains non-ASCII
characters then it will be UTF-8 decoded.

--check-hexstring=STRING
calculate the checksum of a hexadecimal number string.

--check-file=FILE
calculate the checksum of a file. If the file contains non-ASCII characters then it will be UTF-8
decoded.

--generate=CODE
generate C source code; choose the type from {h, c, c-main, table}.

--std=STD
specify the C dialect of the generated code from {C89, ANSI, C99}.

--algorithm=ALGO
choose an algorithm from {bit-by-bit, bbb, bit-by-bit-fast, bbf, table-driven, tbl, all}.

--model=MODEL
choose a parameter set from {crc-5, crc-8, dallas-1-wire, crc-12-3gpp, crc-15, crc-16, crc-16-usb,
crc-16-modbus, crc-16-genibus, crc-16-ccitt, r-crc-16, kermit, x-25, xmodem, zmodem, crc-24, crc-32,
crc-32c, crc-32-mpeg, crc-32-bzip2, posix, jam, xfer, crc-64, crc-64-jones, crc-64-xz}.

--width=NUM
use NUM bits in the Polynomial.

--poly=HEX
use HEX as Polynomial.

--reflect-in=BOOL
reflect the octets in the input message.

--xor-in=HEX
use HEX as initial value.

--reflect-out=BOOL
reflect the resulting checksum before applying the XorOut value.

--xor-out=HEX
xor the final CRC value with HEX.

--slice-by=NUM
speed-up the table-driven calculation by operating on NUM octets of data rather than a single octet
at a time. NUM must be one of the values {4, 8, 16}.

--table-idx-width=NUM
use NUM bits to index the CRC table; NUM must be one of the values {1, 2, 4, 8}.

--force-poly
override any errors about possibly unsuitable polynoms. pycrc does not allow even polynoms or
polynoms that are wider than Width. Use this option to override the error, if you know what you are
doing.

--symbol-prefix=STRING
when generating source code, use STRING as prefix to the exported C symbols.

--crc-type=STRING
when generating source code, use STRING as crc_t type.

--include-file=FILE
when generating source code, include also FILE as header file. This option can be specified multiple
times.

-oFILE, --output=FILE
write the generated code to FILE instead of stdout.

THE CRC PARAMETRIC MODEL

The parametric model follows Ross N. Williams' convention described in A Painless Guide to CRC Error
Detection Algorithms[2], often called the Rocksoft Model. Since most people are familiar with this kind
of parameters, pycrc follows this convention, described as follows:

Width
The number of significant bits in the CRC Polynomial, excluding the most significant 1. This will
also be the number of bits in the final CRC result. In previous versions of pycrc only multiples of 8
could be used as Width for the table-driven algorithm. As of version 0.7.5 any value is accepted for
Width for all algorithms.

Polynomial
The unreflected polynomial of the CRC algorithm.

The Polynomial may be specified in its standard form, i.e. with bit Width+1 set to 1, but the most
significant bit may also be omitted. For example, both numbers 0x18005 and 0x8005 are accepted for a
16-bit Polynomial.

Most polynomials used in real world applications are odd (the least significant bit is 1), but there
are some good even ones. pycrc allows the use of even polynomials with the --force-poly option. Some
even polynomials may yield incorrect checksums depending on the used algorithm. Use at your own risk
and if at all possible use a well-known MODEL above.

ReflectIn
Reflect the octets of the message before processing them.

A word is reflected or reversed by “flipping” its bits around the mid-point of the word. The most
significant bit of the word is moved to the least significant position, the second-most significant
bit is moved to the second-least significant position and so on. The reflected value of 0xa2
(10100010b) is 0x45 (01000101b), for example.

Some CRC algorithms can be implemented more efficiently in a bit reversed version, that's why many of
the standard CRC models use reflected input octets.

XorIn
The initial value (usually all 0 or all 1) for algorithms which operate on the non-augmented message,
that is, any algorithm other than the bit-by-bit one. This value can be interpreted as a value which
will be XOR-ed into the CRC register after Width iterations of the bit-by-bit algorithm. This implies
that the simple bit-by-bit algorithm must calculate the initial value using some sort of reverse CRC
algorithm on the XorIn value.

ReflectOut
Reflect the final CRC result. This operation takes place before XOR-ing the final CRC value with the
XorOut parameter.

XorOut
A value (usually all bits 0 or all 1) which will be XOR-ed to the final CRC value.

Check
This value is not exactly a parameter of a model but it is sometimes given together with the Rocksoft
Model parameters. It is the CRC value of the parametrised model over the string “123456789” and can
be used as a sanity check for a particular CRC implementation.

CODE GENERATION

       In the default configuration, the generated code is strict ISO C99. A minimal set of three functions are
       defined for each algorithm: crc_init(), crc_update() and crc_finalize(). Depending on the number of
       parameters given to pycrc, a different interface will be defined. A fully parametrised model has a
       simpler API, while the generated code for a runtime-specified implementation requires a pointer to a
       configuration structure as first parameter to all functions.

       The generated source code uses the type crc_t, which is used throughout the code to hold intermediate
       results and also the final CRC value. It is defined in the generated header file and its type may be
       overridden with the --crc-type option.

   Fully parametrised models
       The prototypes of the CRC functions are normally generated by pycrc using the --generate h option. The
       CRC functions for a fully parametrised model will look like:

       #include <stdlib.h>
       typedef uint16_t crc_t;         /* pycrc will use an appropriate size here */

       crc_t crc_init(void);

       crc_t crc_update(crc_t crc, const unsigned char *data, size_t data_len);

       crc_t crc_finalize(crc_t crc);

       The code snippet below shows how to use the generated functions.

           #include "pycrc_generated_crc.h"
           #include <stdio.h>

           int main(void)
           {
               static const unsigned char str1[] = "1234";
               static const unsigned char str2[] = "56789";
               crc_t crc;

               crc = crc_init();
               crc = crc_update(crc, str1, sizeof(str1) - 1);
               crc = crc_update(crc, str2, sizeof(str2) - 1);
               /* more calls to crc_update... */
               crc = crc_finalize(crc);

               printf("0x%lx\n", (long)crc);
               return 0;
           }

   Models with runtime-configurable parameters
       When the model is not fully defined then the missing parameters are stored in a structure of type
       crc_cfg_t. If a CRC function requires a value from the crc_cfg_t structure, then the first function
       argument is always a pointer to that structure. All fields of the configuration structure must be
       properly initialised before the first call to any CRC function.

       If the Width was not specified when the code was generated, then the crc_cfg_t structure will contain
       three more fields: msb_mask, crc_mask and crc_shift. They are defined for performance reasons and must be
       initialised to the value given next to the field definition.

       For example, a completely undefined CRC implementation will generate a crc_cfg_t structure as below:

           typedef struct {
               unsigned int width;
               crc_t poly;
               bool reflect_in;
               crc_t xor_in;
               bool reflect_out;
               crc_t xor_out;

               // internal parameters
               crc_t msb_mask;             // initialise as (crc_t)1u << (cfg->width - 1)
               crc_t crc_mask;             // initialise as (cfg->msb_mask - 1) | cfg->msb_mask
               unsigned int crc_shift;     // initialise as cfg->width < 8 ? 8 - cfg->width : 0
           } crc_cfg_t;

       msb_mask is a bitmask with the most significant bit of a Width bits wide data type set to 1.  crc_mask is
       a bitmask with all bits of a Width bits wide data type set to 1.  crc_shift is a shift counter that is
       used when Width is less than 8. It is the number of bits to shift the CRC register to align its top bit
       to a byte boundary.

       The file test/main.c in the source package of pycrc contains a fully featured example of how to use the
       generated source code. A shorter, more compact main() function can be generated with the --generate
       c-main option. This second variant is the better option as it will always output valid code when some of
       the CRC parameters are known and some are unknown during code generation.

EXAMPLES

       Calculate the CRC-32 checksum of the string “123456789”:
           python pycrc.py --model crc-32 --check-string 123456789

       Generate the source code of the table-driven algorithm for an embedded application.
           The table index width of 4 bits ensures a moderate memory usage. To be precise, the size of the
           resulting table will be 16 * sizeof(crc_t).

           python pycrc.py --model crc-16 --algorithm table-driven --table-idx-width 4 --generate h -o crc.h

           python pycrc.py --model crc-16 --algorithm table-driven --table-idx-width 4 --generate c -o crc.c

           A variant of the c target is c-main: this target will generate a simple main() function in addition
           to the CRC functions:

           python pycrc.py --model crc-16 --algorithm table-driven --table-idx-width 4 --generate c-main -o
           crc.c

       Generate the CRC table only:
           python pycrc.py --model kermit --generate table -o crc-table.txt

COPYRIGHT

       This work is licensed under a Creative Commons Attribution-ShareAlike 4.0 International[4].

AUTHOR

       Thomas Pircher <tehpeh-web@tty1.net>
           Author of pycrc and this manual page.

NOTES

        1. pycrc
           https://pycrc.org

        2. A Painless Guide to CRC Error Detection Algorithms
           http://www.ross.net/crc/crcpaper.html

        3. Catalogue of Parameterised CRC Algorithms
           http://reveng.sourceforge.net/crc-catalogue/

        4. Creative Commons Attribution-ShareAlike 4.0 International
           https://creativecommons.org/licenses/by-sa/4.0/

pycrc 0.9.1                                        2017-08-11                                           PYCRC(1)